University of Guelph, Department of Human Health and Nutritional Science, Guelph, ON, Canada.
University of Ottawa, School of Human Kinetics, Faculty of Health Sciences, Ottawa, ON, Canada.
J Mech Behav Biomed Mater. 2019 Jul;95:240-248. doi: 10.1016/j.jmbbm.2019.04.012. Epub 2019 Apr 17.
As the largest and most superficial organ, the skin is well positioned for receiving sensory information from the environment. It is conceivable that changes in posture could result in deformations of the skin and subsequent changes in skin material properties. Specifically, the ankle and metatarsophalangeal joints have the capability to undergo large postural alterations with the potential to induce large structural deformations in the skin of the foot. The purpose of this study was to determine the extent to which alterations in foot posture may influence measures of foot sole and dorsum skin stretch, hardness, and thickness in vivo. Ten young and healthy individuals were tested while three static foot postures (plantar flexion, neutral and dorsiflexion) were maintained passively. Skin stretch deformation was quantified across each posture using an 11 × 4 point matrix of 3D kinematic markers affixed to the skin of the foot sole and dorsum. Skin hardness was assessed across each posture at specific locations of the foot sole (1st metatarsal, 5th metatarsal, medial arch, lateral arch and heel) and foot dorsum (proximal, middle and distal) using a handheld Shore durometer. Skin (epidermal + dermal) thickness was measured in each posture from the same test locations using ultrasound images obtained for the foot sole and dorsum. In the plantar flexion ankle posture, the foot sole skin was observed to relax/retract on average (± standard errorr of the mean (SEM) by 9 ± 2% to become both 20 ± 6% softer and 10 ± 6% thicker. In this posture, the foot dorsum skin stretched on average by 7 ± 2% resulting in 84 ± 8% harder and 5 ± 4% thinner skin. In the dorsiflexion ankle posture, the skin of the foot sole was observed to stretch on average by 5 ± 1% to become both 20 ± 8% harder and 4 ± 7% thinner. In this posture, the skin of the foot dorsum relaxed/retracted on average by 9 ± 1% resulting in the skin becoming 27 ± 12% softer and 7 ± 5% thicker. Notably, all of the sites responded with movement in a similar direction, but each site responded to a variable extent. Importantly, it was clear that the majority of skin structural deformation of the foot sole occurred within the 1st metatarsal, 5th metatarsal, and medial arch regions, while deformation was more evenly distributed across regions of the foot dorsum. The results suggest there is location specificity in the retraction and stretch characteristics of the foot skin. While not tested directly, this may suggest that local stretch distributions could be in part due to the underlying dermal and hypodermal structures in these foot regions. With these observed changes in the mechanical structure of the foot sole and dorsum skin tissue matrix, it is possible that corresponding posture-dependent changes in cutaneous mechanoreceptor activation may be present.
皮肤作为人体最大且最浅表的器官,非常适合接收来自环境的感觉信息。可以想象,姿势的变化可能导致皮肤变形和随后的皮肤材料特性变化。具体而言,踝关节和跖趾关节具有进行大的姿势改变的能力,有可能在足部皮肤中引起大的结构变形。本研究的目的是确定足姿改变在多大程度上可能影响足底和足背皮肤伸展、硬度和厚度的活体测量值。 10 名年轻健康的个体在被动维持三个静态足姿(跖屈、中立和背屈)时进行了测试。使用附在足底和足背皮肤上的 3D 运动学标记的 11×4 点矩阵,在每个姿势下量化皮肤伸展变形。使用手持 Shore 硬度计,在足底(第一跖骨、第五跖骨、内侧弓、外侧弓和脚跟)和足背(近端、中间和远端)的特定部位评估每个姿势下的皮肤硬度。使用从足底和足背获得的超声图像,在每个姿势下测量相同测试部位的皮肤(表皮+真皮)厚度。在跖屈踝关节姿势中,足底皮肤平均观察到放松/缩回(平均值±均方根误差(SEM)为 9±2%),变得更加柔软(20±6%)和更厚(10±6%)。在这个姿势中,足背皮肤平均伸展 7±2%,导致皮肤更加坚硬(84±8%)和更薄(5±4%)。在背屈踝关节姿势中,足底皮肤平均伸展 5±1%,变得更加坚硬(20±8%)和更薄(4±7%)。在这个姿势中,足背皮肤平均放松/缩回(9±1%),导致皮肤更加柔软(27±12%)和更厚(7±5%)。值得注意的是,所有部位都以相似的方向运动,但每个部位的反应程度不同。重要的是,很明显,足底皮肤的大部分结构变形都发生在第一跖骨、第五跖骨和内侧弓区域,而足背区域的变形分布更加均匀。结果表明,足部皮肤的回缩和伸展特征具有位置特异性。虽然没有直接测试,但这可能表明这些足部区域的真皮和皮下组织结构可能部分导致了局部拉伸分布。由于足底和足背皮肤组织基质的机械结构发生了这些观察到的变化,因此可能存在与姿势相关的皮肤机械感受器激活的相应变化。
